Improvement of renal preservation by verapamil with 24-hour cold perfusion in the isolated rat kidney

There is substantial evidence that increased cellular calcium may activate processes that lead to cellular injury and death, and calcium entry blockers (CEB) have been shown to protect against renal ischemic injury. This approach has been used experimentally to enhance kidney preservation during both warm and cold ischemia. In the present study, the effect of the CEB verapamil on kidney function after 24 hr of hypothermic (4-7 degrees C) perfusion was examined and compared with simple cold storage with Eurocollins' solution (4 hr), 4 or 24 hr cold perfusion, without the addition of verapamil. The cold perfusion media consisted of 3% albumin in phosphate-free Krebs-Henseleit saline supplemented with 5 mM glucose. Cold perfusion was performed at 40 mmHg perfusion pressure with either 0 (C) or 5 microM verapamil (V) added to the cold perfusion media. Renal functional parameters of plasma flow (RPF), inulin clearance (Cin), fractional (FRNa+) and net sodium reabsorption (TNa+) were assessed during 60 min of reperfusion at 37 degrees C using 6.7% albumin in Krebs-Henseleit saline supplemented with glucose, inulin, and 20 amino acids. There was no increase in RPF with V (33 +/- 1 vs. 32 +/- 2 ml/min/g,NS) but Cin was significantly higher (271 +/- 30 vs. 168 +/- 20 microliter/min/g P less than 0.01) with V. Preservation of tubular function by V was demonstrated by an increase in FRNa+ (84 +/- 5 vs. 57 +/- 8%, P less than .01), TNa+ (32 +/- 6 vs. 15 +/- 3 mumol/min/g, P less than .01) and renal adenosine triphosphate (ATP) concentration (8.0 +/- 5 vs. 4.7 +/- 1.0 mumol/g dry tissue, P less than .01). Thus, V appears not only to enhance kidney preservation with warm and cold ischemia but also improves renal function, as assessed by glomerular filtration rate (GFR) tubular function, and tissue ATP concentration with 24-hr cold perfusion.     

Exsanguinous metabolic support perfusion--a new strategy to improve graft function after kidney transplantation

BACKGROUND: The compounding damage of warm ischemia (WI) followed by cold preservation is a major barrier in renal transplantation. Although the relative effect of WI is not yet well understood, therapeutic strategies have mostly focused on minimizing the pathology seen upon reperfusion from the cold. Our study was designed to examine the effect of restoration of renal metabolism by warm perfusion on graft survival and to investigate the compounding damage of WI. METHODS: Using a known critical canine autotransplantation model (1), kidneys were exposed to 30 min WI followed by 24 hr cold storage in Viaspan. They were then either reimplanted directly or first transitioned to 3 hr of warm perfusion with an acellular perfusate before reimplantation. Contralateral kidneys were subjected to 0, 30, or 60 min WI; 24 hr cold storage, and 3 hr warm perfusion. RESULTS: Transplanted kidneys that were warm perfused before reimplantation had both lower 24 hr posttransplant serum creatinine (median of 3.2 vs. 4.1 mg/dl) and lower peak serum creatinine (median of 4.95 vs. 7.1 mg/dl). Survival rate for warm perfused kidneys was 90% (9/10) vs. 73% (8/11). In the contralateral kidneys, metabolism was affected by the compounding damage of WI. Renal oxygen and glucose consumption diminished significantly, whereas vascular resistance and lactate dehydrogenase-release rose significantly with increasing WI. CONCLUSIONS: The results demonstrate a reduction of reperfusion damage by an acellular ex vivo restoration of renal metabolism. Furthermore, data from the contralateral kidneys substantiates the relative role of WI on metabolism in renal transplantation.     

Twenty-four hour canine renal preservation by pulsatile perfusion, hypothermic storage, and combinations of the two methods.

A comparison of the effectiveness of two renal preservation techniques was studied in 30 cannine renal pairs. In the absence of warm ischemia, 24-hr preservation by pulsatile perfusion was not significantly superior to hypothermic storage. When 15 min of warm ischemia was added as an additional insult, pulsatile perfusion afforded significantly better early function than cold storage. Combinations of pulsatile perfusion and hypothermic storage following 15 min of warm ischemia were superior to hypothermic storage alone, but inferior to pulsatile perfusion. Kidneys initially perfused for 6 hr and then cold-stored functioned slightly better than kidneys perfused for 18 hr after initial cold storage.     

Cardioprotective effects of tetrahydrobiopterin in cold heart preservation after cardiac arrest.

BACKGROUND: It has recently been shown that tetrahydrobiopterin (BH4), an essential cofactor of nitric oxide synthase (NOS), reduces ischemia-reperfusion myocardial injury. The aim of this study was to determine if supplementation with BH4 after cardiac arrest followed by cold heart preservation would exert a cardioprotective effect against ischemia-reperfusion injury. MATERIALS AND METHODS: Isolated perfused rat hearts were subjected to 4 degrees C cold ischemia and reperfusion. Hearts were treated with cold cardioplegic solution with or without BH4 just before ischemia and during the first 5 min of reperfusion period. Effects of BH4 on left ventricular function, myocardial contents of high-energy phosphates, and nitrite plus nitrate were measured in the perfusate, before ischemia and after reperfusion. Moreover, the effect of BH4 on the cold-heart preservation followed by normothermic (37 degrees C) ischemia was determined. RESULTS: BH4 improved the contractile and metabolic abnormalities in reperfused cold preserved hearts that were subjected to normothermic ischemia. Furthermore, BH4 significantly alleviated ischemic contracture during ischemia, and restored the diminished perfusate levels of nitrite plus nitrate after reperfusion. CONCLUSION: These results demonstrated that BH4 reduces ischemia-reperfusion injury in cold heart preservation. The cardioprotective effect of BH4 implies that BH4 could be a novel and effective therapeutic option in the preservation treatment of donor heart after cardiac arrest.     

Protection of autotransplanted pig kidneys from ischemia-reperfusion injury by polyethylene glycol

BACKGROUND: Ischemia-reperfusion injury (IRI) is often responsible for graft rejection and leads to delayed graft function of cadaveric kidneys. We have shown that adding polyethylene glycol (PEG 20M) to the preservation solutions helps protect isolated perfused pig kidneys against cold ischemia and reperfusion injury. METHODS: We compared the effects of adding PEG to a simplified high-K+ perfusion solution of cold-stored kidneys to Euro-Collins or University of Wisconsin solutions on the function of reperfused autotransplanted pig kidneys. The left kidney was cold-flushed with the preservation solutions and stored for 48 hr at 4 degrees C before reimplantation. Creatinine clearance and fractional excretion of sodium were analyzed 2 days before surgery and over 7 days after transplantation. Histological sections were obtained 40 min after reperfusion and on day 7 after surgery. RESULTS: Adding PEG to the perfusate significantly reduced IRI from autotransplanted pig kidneys. Creatinine clearance was significantly higher and fractional excretion of sodium was significantly lower in pigs transplanted with kidneys cold-flushed with PEG-supplemented perfusate than in those flushed with Euro-Collins or University of Wisconsin solutions. PEG supplementation also better preserved the integrity of kidney cells and markedly reduced interstitial cell infiltrates. CONCLUSION: PEG protects against IRI and reduces early cellular inflammation. PEG may impair the recruitment and migration of leukocytes into retransplanted pig kidneys. Cold preservation of donor organs with PEG-supplemented solutions may therefore help limit IRI in human renal transplantation.     

Verapamil improves rat hepatic preservation with UW solution

Verapamil, a calcium channel blocker, improves myocardial preservation during cold cardioplegia and protects against renal damage during periods of warm and cold ischemia. To determine if verapamil could prevent ischemic damage to livers during and after cold storage, harvested rat livers were flushed with either University of Wisconsin (UW) solution or UW solution with 25 mg/liter verapamil. Twenty rats were used in each group. After 24 hr of storage at 4 degrees C, livers were perfused with oxygenated blood through the portal veins for 2 hr at 37 degrees C and pH 7.4. Liver enzymes, electrolytes, and perfusate flow rate were determined at 30-min intervals. At 90 min of perfusion, the verapamil group of livers had less elevation of AST (110 +/- 17 IU/liter vs 172 +/- 25 IU/liter, P less than 0.05), ALT (115 +/- 21 IU/liter vs 210 +/- 34 IU/liter, P less than 0.05), and LDH (962 +/- 170 IU/liter vs 1452 +/- 253 IU/liter, NS). Verapamil livers produced more bile than controls (6.9 +/- 1.9 microliters/g vs 2.3 +/- 1.7 microliter/g, P less than 0.05) and maintained a higher portal flow rate throughout the perfusion. Both groups showed similar reduction in liver weights after storage (3.9 +/- 0.9% vs 2.8 +/- 0.7%) and required the same amount of bicarbonate for correction of acidosis during perfusion (2.6 +/- 0.2 mM vs 2.8 +/- 0.2 mM). Light microscopic exam after perfusion showed hepatocyte damage in 30% of control livers, but 0% of verapamil livers. We conclude that verapamil-treated rat livers showed less damage and better function upon reperfusion after 24 hr of cold storage. This agent may be clinically useful as an additive to the UW preservation solution for livers.     

Cold flush after dynamic liver preservation protects against ischemic changes upon reperfusion – an experimental study

Ex vivo machine perfusion of the liver after cold storage has found to be most effective if combined with controlled oxygenated rewarming up to (sub)‐normothermia. On disconnection of the warm graft from the machine, most surgeons usually perform a cold flush of the organ as protection against the second warm ischemia incurred upon implantation. Experimental evidence, however, is lacking and protective effect of deep hypothermia has been challenged for limited periods of liver ischemia in other models. A first systematic test was carried out on porcine livers, excised 30 min after cardiac arrest, subjected to 18 h of cold storage in UW and then machine perfused for 90 min with Aqix‐RSI solution. During machine perfusion, livers were gradually rewarmed up to 20 °C. One group (n = 6) was then reflushed with 4 °C cold Belzer UW solution whereas the second group (n = 6) remained without cold flush. All livers were exposed to 45 min warm ischemia at room temperature to simulate the surgical implantation period. Organ function was evaluated in an established reperfusion model using diluted autologous blood. Cold reflush after disconnection from the machine resulted in a significant increase in bile production upon blood reperfusion, along with a significant reduction in transaminases release alanine aminotransferase and of the intramitochondrial enzyme glutamate dehydrogenase. Interestingly, free radical‐mediated lipid peroxidation was also found significantly lower after cold reflush. No differences between the groups could be evidenced concerning histological injury and recovery of hepatic energy metabolism (tissue content of adenosine triphosphate). Post‐machine preservation cold reflush seems to be beneficial in this particular setting, even if the organs are warmed up only to 20 °C, without notion of adverse effects, and should therefore be implemented in the protocol.     

Effect of experimental cardioplegia methods on normal and hypertrophied rat hearts

The purpose of this study was to evaluate whether the addition of verapamil hydrochloride to oxygenated glucose-rich cardioplegic solution would improve myocardial preservation. The Langendorff preparation of the isolated rat heart was used. Groups of normal (WKY) and hypertrophied (SHR) hearts were treated by five different cardioplegic methods and subjected to 90 or 30 minutes of ischemia at 28 degrees to 29 degrees C and reperfusion at 37 degrees C. The following cardioplegic solutions were used: Group A, cold (16 degrees C) Krebs-Henseleit (KH) glucose free only; Group B, KH with KCL (30 mEq/L) (16 degrees C); Group C, same as B with verapamil (10 microM); Group D, perfusion with oxygenated KH solution containing KCL (30 mEq/L) for 15 minutes prior to ischemia; and Group E, same as D with verapamil (10 microM). Recovery of contraction amplitude, ischemic contracture, coronary perfusate volume, the amount of creatine kinase in the coronary perfusate, heart rate, time of revival, O2 consumption, and ischemic contracture were measured. After 30 minutes of ischemia, we did not find any significant difference among the combinations tested with respect to contraction amplitude recovery. The hearts recovered fully. After 90 minutes of ischemia, we found that the best-protected groups in the normal hearts were Groups D and E. In the hypertrophied hearts, the addition of verapamil to the enhancement solution was harmful. The use of enhancement solution without verapamil prior to ischemia provided the best myocardial protection in the hypertrophied hearts.     

Preservation of pig liver allografts after warm ischemia: normothermic perfusion versus cold storage

Warm ischemia is known to induce substantial damage to the liver parenchyma. With respect to clinical liver transplantation, the tolerance of the liver to warm ischemia and the preservation of these organs have not been studied in detail. In isolated reperfused pig livers we proceeded according to the following concept: Livers were subjected to 1 or 3 h of warm ischemia. Subsequently, these organs were preserved by either normothermic perfusion or cold storage (histidine-tryptophan-α-ketoglutarate, HTK) for 3 h each. After storage, liver function was assessed in a reperfusion circuit for another 3 h. Parameters under evaluation were bile flow, perfusion flow, oxygen consumption, enzyme release into the perfusate (creatine kinase, glutamic oxaloacetic transaminase (GOT), lactic dehydrogenase, and glutamic pyruvic transaminase), and histomorphology. Damage to the liver was lowest after warm ischemia of 1 h. The results after cold storage were superior to those after normothermic perfusion (GOT: 3.2±0.3 and 2.6±0.2 U/g liver; cumulative bile production: 14.7±2.1 and 9.4±1 ml, respectively;P<0.05). In contrast, we found substantial damage at the end of reperfusion in livers undergoing 3 h of warm ischemia under both preservation techniques with severe hepatocellular pyknoses and essentially altered nonparenchymal cells. The results suggest that pig livers undergoing 1 h of warm ischemia and cold storage for 3 h with HTK solution may lead to functioning after transplantation.     

Cold preservation mediated renal injury: involvement of mitochondrial oxidative stress

Cold preservation has greatly facilitated the use of cadaveric kidneys for renal transplantation, but, clearly, damage occurs during both the preservation episode and the reperfusion phase (following transplantation). The aims of this study were twofold: to develop an in vivo model that was capable of evaluating renal function at early time points following cold preservation, and to evaluate the extent of renal mitochondrial damage that occurs following short periods of cold preservation in vivo. To accomplish these goals, we developed a novel rat model of in vivo renal cold ischemia followed by warm reperfusion (cold I/R) which avoided the complexity involved with transplantation. Briefly, after a right nephrectomy, cold I/R was initiated via pulsatile perfusion (40 minutes) of the left kidney with a cold University of Wisconsin solution followed by 18 hours of warm reperfusion. Cold I/R resulted in significant renal injury, nitrotyrosine production, and inactivation of the key mitochondrial antioxidant enzyme, manganese superoxide dismutase. Furthermore, the activities of the mitochondrial respiratory complexes were significantly reduced following cold I/R. In conclusion, short-term cold I/R results in inactivation of MnSOD, which may lead to the inhibition of mitochondrial complexes and subsequent renal injury. These data suggest that compounds designed to prevent early mitochondrial injury in kidneys that undergo cold preservation would significantly improve renal function and graft survival following transplantation.     

Short-term outcome of kidney transplants from non-heart-beating donors after preservation by machine perfusion

Abstract  In this study, the short-term outcome of renal transplants from non-heart-beating donors (NHBD) preserved by machine perfusion (MP) is evaluated and compared to preservation by cold storage (CS). Twenty-two NHBD kidneys were procured during 1993 and 1994 after in situ perfusion with his-tidine-tryptophan ketoglutarate and preserved by continuous perfusion using University of Wisconsin organ preservation solution for MP as a perfusate. Between 1980 and 1992, 57 NHBD kidneys were procured and preserved by CS. Donors in the MP group sustained increased first warm ischemia times (WITI) ( P < 0.1) and recipients in the MP group suffered longer anastomosis time, worse HLA-DR mismatch, and more initial use of cyclosporin as immunosuppressant; all these factors are known to be deleterious to short-term outcome. Despite these unfavorable conditions, delayed function (DF) rate was decreased in the MP group, although not significantly. However, when considering only kidneys with WI ± 45 min, short-term outcome was significantly better in the MP group ( P < 0.05). We conclude that MP is superior for the preservation of NHBD kidneys, especially after prolonged warm ischemia.     

Evaluation of a preservation solution containing fructose-1,6-diphosphate and mannitol using the isolated perfused rat kidney. Comparison with Euro-Collins and University of Wisconsin solutions

The renal preservation ability of a flushing solution (F-M)with fructose-1,6-diphosphate (1 g/dl) and mannitol (2 g/dl)during cold ischaemia was studied with the isolated perfusedrat kidney model and compared with the Euro-Collins (EC) andUniversity of Wisconsin (UW) solutions. Kidneys were storedin hypothermia for 4 and 18 h after initial flushing with thesolution being tested, and then reperfused at 37°C in anisolated perfusion circuit for 90 min with a Krebs-Henseleitsolution containing 4.5% albumin. Forty-four kidneys were studied and divided in a control groupand six study groups according to the cold ischaemia time andflushing solution used. Renal functional parameters of plasmaflow rate (PFR), renal vascular resistance (RVR), urine flowrate (UFR) glomerular filtration rate (GFR), fractional (FRNa)and net (TNa) sodium reabsortion were assessed during reperfusion.Conventional histology and malon-dialdehyde tissue levels (MDA)were also evaluated. Our results show that PFR, RVR, and UFR were similar in allstudy groups. After 4 and 18 h of cold ischaemia, GFR, FRNaand TNa were better, and conventional histology worse in F-Mthan in EC flushed kidneys. After 4 and 18 h of cold ischaemia,GFR, FRNa and TNa, in fact, were not different between F-M andUW flushed kidneys. After 4 h of cold ischaemia, conventionalhistology was similar in F-M and UW flushed kidneys. Nevertheless,after 18 h of cold ischaemia, UW flushed kidneys showed worsehistological parameters than F-M flushed kidneys. After 4 hof cold ischaemia, MDA was similar in kidneys flushed with thethree solutions. After 18 h of cold ischaemia MDA was higherin EC than in F-M or UW flushed kidneys. In summary, our newly developed cold storage solution showspromising results in renal preservation and its ability to preserveis at least as good as UW solution assessed in the isolatedperfused rat kidney.     

Overcoming severe renal ischemia: the role of ex vivo warm perfusion

BACKGROUND: The ability to effectively utilize kidneys damaged by severe (2 hr) warm ischemia (WI) could provide increased numbers of kidneys for transplantation. The present study was designed to examine the effect of restoring renal metabolism after severe WI insult during ex vivo warm perfusion using an acellular technology. After warm perfusion for 18 hr, kidneys were reimplanted and evaluated for graft function. METHODS: Using a canine autotransplant model, kidneys were exposed to 120 min of WI. They were then either reimplanted immediately, hypothermically machine perfused (4 degrees C) for 18 hr with Belzer's solution, or transitioned to 18 hr of warm perfusion (32 degrees C) with an acellular perfusate before implantation. RESULTS: Warm perfused kidneys with 120 min of WI provided life-sustaining function after transplantation, whereas the control kidneys immediately reimplanted or with hypothermic machine perfusion did not. The mean peak serum creatinine in the warm perfused kidneys was 3.7 mg/dl, with the mean peak occurring on day 2 and normalizing on day 9 posttransplant. CONCLUSIONS: These results indicate that 18 hr of ex vivo warm perfusion of kidneys is feasible. Furthermore, recovery of renal function during warm perfusion is demonstrated, resulting in immediate function after transplantation. The use of ex vivo warm perfusion to recover function in severe ischemically damaged kidneys could provide the basis for increasing the number of transplantable kidneys.     

Decrease in core liver temperature with 10 degrees C by in situ hypothermic perfusion under total hepatic vascular exclusion reduces liver ischemia and reperfusion injury during partial hepatectomy in pigs

OBJECTIVE: We attempted to assess liver ischemia/reperfusion injury under a mild decrease in core liver temperature of 10 degrees C by in situ hypothermic perfusion during ischemia. METHODS: Liver ischemia was induced in pigs by total hepatic vascular exclusion with concomitant in situ perfusion with hypothermic (4 degrees C) Ringer-glucose (cold perfused group, core liver temperature maintained at 28 degrees C), with normothermic (38 degrees C) Ringer-glucose (warm perfused group) or without in situ perfusion (control group). RESULTS: In the cold perfused, warm perfused, and control groups, 24-hour survival was 5/5, 0/5, and 3/5, respectively. Hemodynamic parameters in the cold perfused group remained stable, whereas pigs in both other groups required circulatory support. Plasma AST and interleukin-6 levels were lower in the cold perfused group than in both other groups. Hepatocellular function was best preserved in the cold perfused group as indicated by complete recovery of bile production during reperfusion and no loss of indocyanine green clearance capacity. In both other groups, bile production and indocyanine green clearance capacity were reduced significantly. The hyaluronic acid uptake capacity of pigs in the cold perfused group or control group did not differ, indicating preserved sinusoidal endothelial cell function. Histopathologic injury scores during reperfusion were significantly lower in the cold perfused group when compared to both other groups. CONCLUSIONS: A mild decrease in core liver temperature of 10 degrees C by in situ hypothermic liver perfusion during ischemia protects the liver from ischemia/reperfusion injury. This protection appears to be related to cooling of the liver rather than to the washout of blood during perfusion.     

Effect of pharmacologic agents on the function of the hypothermically preserved dog kidney during normothermic reperfusion

We examined how a combination of pharmacologic agents ("rescue" agents) affect the function of hypothermically preserved dog kidneys at the time of reperfusion. Dog kidneys were preserved either by simple cold storage in EuroCollins' solution for 24 or 48 hours or by continuous perfusion at 5 degrees C in Belzer's gluconate-hydroxyethyl starch solution for as long as 5 days. After preservation, renal functions were measured with the isolated perfused kidney model. Kidneys were reperfused at normothermia either with or without the addition of a combination of rescue agents to the reperfusion medium. The rescue agents studied were allopurinol (1 mmol/L); superoxide dismutase (32,000 U/L); catalase (137,500 U/L); dimethylthiourea (3 mmol/L); glutathione (3 mmol/L); desferrioxamine (0.2 gm/L), for protection against O2 free radical injury and lipid peroxidation injury; verapamil (25 mg/L), as a Ca channel blocker; and ATP-MgCl2 (0.3 mmol/L), to stimulate energy metabolism. The renal functions we measured were glomerular filtration rate (GFR) (creatinine clearance), urine production, perfusate flow, urinary protein concentration, Na reabsorptive capacity, and tissue concentrations of ATP, K, and total tissue water. GFR was reduced by 75% to 90% after all periods of preservation, and the rescue agents had no effect on GFR. Sodium reabsorption was reduced from 98% to a range of 40% to 50% after 48 hours of cold storage or 5 days of machine perfusion and was not increased by rescue agents. There was a time-dependent increase in the amount of urine protein that was not affected by rescue agents. The addition of rescue agents did not affect total tissue water or concentrations of ATP or K in kidneys after normothermic reperfusion. These results demonstrate that pharmacologic agents previously suggested to suppress reperfusion damage in kidneys are not effective in this model. Therefore it is likely that kidneys damage occurs primarily during preservation, which suggest that optimal function on reperfusion calls for the development of better methods of preservation.     

Propionyl-L-carnitine prevents renal function deterioration due to ischemia/reperfusion

BACKGROUND: Ischemia-reperfusion injury after organ transplantation is a major cause of delayed graft function. Prevention of post-transplant ischemia acute renal failure is still elusive. METHODS: The present study was designed to examine whether propionyl-l-carnitine, an acyl derivative of carnitine involved in fatty acid oxidation pathway and adenosine 5'-triphosphate (ATP) generation of mitochondria, prevented renal function deterioration and structural injury induced by ischemia-reperfusion in an ex vivo rat model of isolated perfused kidney (IPK) preparation and in vivo in a model of syngeneic kidney transplantation. RESULTS: In the model of ischemia (20 or 40 min)/reperfusion (90 or 70 min) in IPK, untreated kidneys showed a marked reduction of glomerular filtration rate (GFR) and renal perfusate flow (RPF) as compared to baseline, when perfusion was established by restoring effective perfusion pressure to 100 mm Hg. Exposure of kidneys to propionyl-l-carnitine before establishing the ischemia insult to tissue, largely prevented renal function impairment. Pre-exposure of ischemic kidneys to propionyl-l-carnitine largely reduced the percent of lactate dehydrogenase (LDH), a cell injury marker, released into the perfusate after reperfusion as compared to untreated ischemic kidneys. Histologic findings showed very mild post-ischemic lesions in kidneys exposed to propionyl-l-carnitine as compared to untreated ischemic kidneys. Immunohistochemical detection of 4-hydroxynonenal protein adduct, a major product of lipid peroxidation, was very low in kidney infused with propionyl-l-carnitine and exposed to ischemia/reperfusion as compared to untreated ischemic kidneys. ATP levels were not affected by propionyl-l-carnitine treatment. Renal function of kidneys exposed for four hours to cold Belzer UW solution added with propionyl-l-carnitine and transplanted to binephrectomized recipients was largely preserved as compared to untreated ischemic grafts. Propionyl-l-carnitine almost completely prevented polymorphonuclear cell graft infiltration and reduced tubular injury at 16 hours post-transplant. CONCLUSIONS: These data indicate that propionyl-l-carnitine is of value in preventing decline of renal function that occurs during ischemia-reperfusion. The beneficial effect of propionyl-l-carnitine possibly relates to lowering lipid peroxidation and free radical generation that eventually results in the preservation of tubular cell structure. The efficacy of propionyl-l-carnitine to modulate ischemia-reperfusion injury in these models opens new perspectives for preventing post-transplant delayed graft function.     

Euro-Collins solution versus UW-solution for long-term liver preservation in the isolated rat-liver perfusion model.

To compare UW-solution (UW) and Euro-Collins (EC) for long-term liver preservation we investigated the morphology and metabolic capacity of rat liver after 18 and 42-hours cold-storage in either UW or EC. After harvesting the rat liver was transferred to a perfusion chamber where it was perfused for 10 min with UW or EC at 4 degrees C. Thereafter livers were stored at 4 degrees C in UW or EC for 18 hours (both groups n = 6) or for 42 hours (both groups n = 8). After 18-hr or 42-hr cold-storage a 2-hr warm perfusion (37 degrees C) was started with Krebs-Ringer solution with carbogen to which 125Iodine-triiodothyronine (T3) was added. Control livers (n = 8) were immediately perfused with Krebs-Ringer without cold-storage. The following parameters were assessed: ASAT-levels in the perfusate, T3-metabolites in the bile and the perfusate, the perfusion pressure, the volume of bile secreted and light-microscopical morphology at the end of the warm perfusion period. After cold storage in UW-solution the ASAT-levels in the perfusate were lower than after storage in EC as well as the perfusion pressures. These livers demonstrated a better T3-metabolism and secreted more bile than EC-stored livers. Histological examination showed more tissue damage in the EC-stored livers than in the UW stored livers. We conclude that cold-storage of rat liver in UW-solution resulted in a better morphology and metabolic capacity as compared with EC-solution.     

An In Vivo Autotransplant Model of Renal Preservation: Cold Storage Versus Machine Perfusion in the Prevention of Ischemia/Reperfusion Injury

There is increasing proof that organ preservation by machine perfusion is able to limit ischemia/reperfusion injury in kidney transplantation. This study was designed to compare the efficiency in hypothermic organ preservation by machine perfusion or cold storage in an animal model of kidney autotransplantation.
Twelve pigs underwent left nephrectomy after warm ischemic time; the organs were preserved in machine perfusion ( n  = 6) or cold storage ( n  = 6) and then autotransplanted with immediate contralateral nephrectomy. The following parameters were compared between the two groups of animals: hematological and urine indexes of renal function, blood/gas analysis values, histological features, tissue adenosine-5'-triphosphate (ATP) content, perforin gene expression in kidney biopsies, and organ weight changes were compared before and after preservation.
The amount of cellular ATP was significantly higher in organs preserved by machine perfusion; moreover, the study of apoptosis induction revealed an enhanced perforin expression in the kidneys, which underwent simple hypothermic preservation compared to the machine-preserved ones. Organ weight was significantly decreased after cold storage, but it remained quite stable for machine-perfused kidneys.
The present model seems to suggest that organ preservation by hypothermic machine perfusion is able to better control cellular impairment in comparison with cold storage.     

Functional recovery of preserved livers following warm ischemia: improvement by machine perfusion preservation

BACKGROUND: Hypothermic machine perfusion preservation has the potential to relieve the current donor shortage problem by reclaiming and preserving marginal donor organs including those from viable non-heart-beating donors. A number of problems exist with the current machine perfusion technology for preserving livers, and much research is needed to determine the clinical impact of this technology in preserving non-heart-beating donor livers. METHODS: This study was conducted to compare the poststorage function and microcirculation of simple cold stored and machine perfusion preserved livers that had experienced 30 min of warm ischemia followed by a 10 hr preservation period. In an isolated rat liver perfusion model, lactate dehydrogenase activity, indocyanine green secretion, and portal pressure values were determined at major time points. An intravital microscopy was conducted to assess microcirculation. RESULTS: The results showed an increase in flow homogeneity of machine perfused livers, which correlated with the reduction in portal pressure when compared with simple cold storage (5.4+/-0.4 vs. 8.7+/-0.6 mm Hg). A reduction in lactate dehydrogenase levels in the perfusate (333+/-22 vs.103+/-8 U/L) and an increase in bile production of the machine perfused livers (4.9+/-0.5 vs. 33.2+/-1.7 microg/min/g liver) and indocyanine green secretion (11.7+/-1.7 vs. 21.2+/-2.1 Abs/g bile) were observed at all time points (mean+/-SE of final point given). Intravital microscopic examination indicated that large regions of non flow, as indicated by the absence of fluorescein isothiocyanate-labeled albumin, were observed in the simple cold stored tissue, whereas machine perfused liver showed increase flow homogeneity. Values of bile production, indocyanine secretion, and cellular damages were comparable with controls. Histologic examination confirmed that simple cold stored tissue displayed increased vacuolization, and machine perfused tissue showed regions of normal hepatic structure. CONCLUSION: These results suggest that machine perfusion for 10 hr improves both poststorage function and microcirculation while reducing cellular damage of liver tissue that has experienced 30 min of warm ischemia, when compared with simple cold storage. Further studies need to be conducted, but this study suggests that machine perfusion preservation has the potential to reclaim and preserve liver tissues after warm ischemic insult.     

Hepatic control of perfusate homeostasis during normothermic extrocorporeal preservation

BACKGROUND: We investigated the ability of the isolated porcine liver to maintain acid-base homeostasis in the perfusate and the impact of ischemia-reperfusion injury without or with extracorporeal perfusion. METHODS: Harvested livers were either stored for 24 hours in cold University of Wisconsin solution or preserved by continuous, normothermic, oxygenated sanguineous perfusion with supplemental nutrition, prostacyclin, and bile salts. After a further 24-hour period of reperfusion of both groups on an extracorporeal circuit, the perfusate was assessed for both biochemical indices of synthetic and metabolic liver function as well as hepatocellular injury and blood gas analysis. RESULTS: Livers injured by cold ischemia during preservation displayed inferior synthetic and metabolic functions. Perfused livers, which displayed minimal ischemic injury, produced more bicarbonate than the cold-stored organs, suggesting autoregulation of pH homeostasis in perfused livers in contrast to progressively worsening acidosis in cold-stored organs. CONCLUSIONS: Given proper physiologic substrate the porcine liver has the ability to maintain acid-base homeostasis, provided there is not a significant ischemia-reperfusion injury.